Automatic control of extrusion

ABSTRACT

The actual temperature of the extrudate issuing from a long land die extruder is measured and a measurement signal representative thereof is established. The measurement signal is then compared with a setpoint signal representing the desired extrudate temperature to produce a control signal which is responsive to the difference between the measurement signal and the setpoint signal. The cooling fluid being circulated in heat exchange relationship with the extrudate in the long land die is manipulated responsive to the control signal to maintain the actual temperature of the extrudate substantially at the desired extrudate temperature. When the magnitude of the difference between the measurement signal and the setpoint signal exceeds a predetermined value, the rate of heat input to the plasticization section of the extruder and/or the rate of extrusion of the extrudate can be varied to reduce said difference to less than said predetermined value.

This application is a division of copending application Ser. No. 666,287, filed Mar. 12, 1976, now U.S. Pat. No. 4,088,430.

This invention relates to the extrusion of thermoplastic material. In a specific aspect the invention relates to dynamic extrusion with a long land die in which at least the outer portions of the extrudate are solidified prior to leaving the die, and more particularly to method and apparatus for automatically manipulating the cooling of the extrudate in the long land die to maintain the temperature of the extrudate at the outlet of the long land die substantially constant. In another aspect the invention relates to method and apparatus for varying the heat input to the extruder and/or the rate of extrusion when the magnitude of the difference between the actual and desired extrudate temperatures exceeds a predetermined value.

It is common practice to produce articles from thermoplastic resins by extrusion processes wherein the resin is melted and forced through a die under pressure to form the article. This process is particularly useful in forming elongated articles such as pipes, bars, rods and the like. One extrusion method that has recently been developed is commonly referred to as "dynamic extrusion". The concept of dynamic extrusion includes the successive steps of compacting and transferring a multitude of thermoplastic particles through a heated plasticization zone to melt the particles into a pliable mass and then advancing the pliable mass into a long land die of particular cross-sectional configuration wherein at least the outer portions of the thermoplastic material of the extrudate solidify before leaving the die. While the dimensions of long land dies can vary considerably, depending upon the polymer, the extruder, the dimensions of the extrudate and the designed production rate, the die will generally have a land length in the range of about 10 to about 100 times the thickness of the extrudate. The foregoing steps can be effected by means of a piston which reciprocates in a passageway to force the particles of thermoplastic material, fed to the extruder, through the heated plasticization zone and the long land die. The dynamic extruder method requires a considerable amount of heat in order to melt the thermoplastic particles so that they can be passed through the plasticization chamber and into the long land die. Part of this heat is provided by the mechanical working of the thermoplastic material as it is passed through the plasticization chamber, and the balance of the heat is provided by external heaters.

In extrusion processes, particularly those involving the use of long land dies, one of the factors which limits production is the rate at which heat can be removed from the extrudate as it moves through the die. In order to provide adequate cooling, it is common practice to circulate a cooling fluid through heat exchangers adjacent the die passage. If a hollow article such as a pipe is being extruded, heat exchangers are often positioned both externally and internally of the die passage. The resulting cooling causes the resin to solidify and to shrink slightly. Because of this shrinkage, the surfaces of the extrudate may not remain in firm contact with the die. The resulting air gap acts on an insulator which tends to reduce the rate at which heat is removed. One solution to this problem involves the use of a tapered die to compensate for shrinkage as the resin solidifies. A die of this type is described in U.S. Pat. No. 3,393,427. The final dimensions of the extrudate depend upon the degree of pre-extrusion shrinkage of the extrudate, which is determined by the extrudate surface temperature at the die exit. However, if the cooling rate does not correspond to the cooling requirements, the surface temperature of the extrudate at the outlet of the long land die will vary from the optimum value therefor. If the extrudate surface temperature is too high, the amount of the polymer in the extrudate which has solidified will be insufficient to provide dimensional stability of the extrudate during the postextrusion period of time necessary to complete the solidification of the polymer. If the extrudate surface temperature is too low, the shrinkage of the extrudate causes an excessive increase in friction between the mandrel and the extrudate and spider lines form when the polymer is too cool to unite after passing a spider. Thus it is highly desirable to be able to maintain the extrudate surface temperature within a safe intermediate zone and preferably at least substantially constant at a predetermined value in the intermediate zone.

Variations in the cooling requirements occur with changes in extrusion rate and with changes in the temperature of the molten polymer entering the long land die section of the extruder. Variations in the temperature of the molten polymer entering the long land die section can occur because of variations in extrusion rate, variations in voltage to electrical heaters or gas flow rate to gas burners, variations in the environment such as drafts and atmosheric temperature, etc. Variations in extrusion rate can occur because of variations in polymer particle configuration, varying depth of polymer particles in the supply hopper, variations in voltage to the vibrator, etc.

For a particular extruder with a particular die configuration and a given cooling capacity for the long land die, there is an optimum extrusion rate. However, as variations can occur in the feed rate of the thermoplastic material and in the melt temperature, it has been necessary to operate at a value of extrusion rate which is significantly less than the optimum extrusion rate in order to avoid exceeding the available cooling capacity. As the difference between operating extrusion rate and optimum extrusion rate represents a significant loss in capacity, it would be highly advantageous to substantially decrease, and preferably eliminate, the difference between the operating extrusion rate and the optimum extrusion rate.

Accordingly it is an object of the present invention to maintain the surface temperature of the extrudate at the outlet of a long land die section of an extruder in a safe operating range. Another object of the invention is to maintain the extrudate surface temperature at the die outlet substantially constant at a predetermined value. A further object of the invention is to provide sufficient dimensional stability for an extrudate as it issues from a long land die. Another object of the invention is to prevent spider lines in an extrudate. It is an object of the invention to avoid excessive friction between an extrudate and a mandrel. Another object is to increase the operating extrusion rate. A further object of the invention is to minimize the effects of uncontrolled variations in the operation of the polymer particles feeder on the extrudate temperature. A further object of the invention is to maximize the extrusion rate without exceeding the cooling capacity of the long land die. Another object of the invention is to adjust the feed rate of polymer particles to the extruder responsive to variations in the temperature of the polymer melt and to variations in the extrudate temperature. Yet another object of the invention is to provide an extrusion control system which readily adjusts to major changes in desired extrusion rate and/or desired extrudate surface temperature. Other objects, aspects and advantages of the invention will be apparent from a study of the specification, the drawings and the appended claims to the invention.

In accordance with the present invention there are provided automatic control method and apparatus for producing a signal representative of the actual extrudate surface temperature at the outlet of the long land die, comparing the thus produced signal with a signal representative of the desired extrudate surface temperature, and automatically manipulating the cooling fluid being passed in heat exchange relationship with the extrudate in the long land die section responsive to the difference between the thus compared signals. In one embodiment, there are also provided method and apparatus for establishing a measurement signal representative of the actual rate of extrusion, comparing the measurement signal with a signal representative of the desired rate of extrusion, automatically manipulating the feed rate of polymer to the plasticization section of the extruder responsive to the difference between the thus compared signals, and modifying the manipulation of the feed rate of polymer when the magnitude of the difference between the actual and desired extrudate surface temperature exceeds a predetermined value to reduce the difference between the actual and desired extrudate surface temperature to less than said predetermined value.

In a presently preferred embodiment there are also provided method and apparatus for establishing a measurement signal representative of the actual temperature of the molten thermoplastic material at the inlet of the long land die, providing a setpoint signal representative of the desired temperature for the molten thermoplastic material at the inlet of the long land die, subtracting the setpoint signal from the measurement signal, automatically varying responsive to the difference thereby obtained the heat input to the polymer in the extruder, and automatically modifying the control of the heat input to the polymer in the extruder when the magnitude of the difference between the actual and desired extrudate surface temperatures exceeds a predetermined value to reduce the magnitude of the difference between the actual and desired extrudate surface temperatures to less than said predetermined value.

In the drawings

FIG. 1 is a diagrammatic illustration of a dynamic extrusion system embodying the present invention, and

FIG. 2 is a schematic illustration of a triac circuit suitable for use in the system of FIG. 1.

Referring now to the drawing in detail, there is shown a dynamic extruder having a long land die section 11, a heating section 12, and a feed inlet section 13, supported by a frame 14. A piston 15 is connected to fly wheel 16 by means of a connecting rod 17 and a crosshead 18. The piston 15 is mounted for reciprocal motion in the feed inlet section 13. A motor 19 serves to impart at least substantially constant rotational motion to fly wheel 16 by means of belt 21.

A thermoplastic material in particle form, e.g. pellets, powder, or fluff, can be charged to storage hopper 22 by conveying means 23. A chute 24 is positioned below the outlet of storage hopper 22 for transmitting the thermoplastic particles from storage hopper 22 to a feed hopper 25 on feed inlet section 13. An electrically actuated vibrator means 26 is attached to chute 24 such that the flow of polymer particles from storage hopper 22 to feed hopper 25 is effected by vibrator means 26 at a rate responsive to the degree of excitation of vibrator means 26. The polymer particles are passed through feed hopper 25 into feed inlet section 13 where the polymer particles are compressed by piston 15, passed into heating section 12 and converted into molten thermoplastic material. The molten material enters long land die section 11, which is cooled by the flow of cooling water from conduit 31 through cooling passageways in die section 11 into conduit 32. The temperature of the cooling water in conduit 31 can be maintained at substantially constant at a desired value by cooling water temperature controller 33. Makeup cool water, e.g. tap water, is supplied to controller 33 via conduit 34, while warm water can be discharged to a drain via conduit 35. Temperature controller 33 can be provided with a pump, a recirculation line and appropriate valving so that at least a portion of the warm water from conduit 32 can be recirculated to the die section 11 via conduit 31. The controller 33 can also be provided with a heater to elevate the temperature of the water passing to conduit 31 as may be required, particularly during startup. Thus, temperature controller 33 maintains the temperature of the cooling water delivered to die section 11 at a predetermined desired temperature which corresponds to setpoint 36, by varying the amount of warm water dumped via conduit 35 and cool tap water added via conduit 34 and/or by controlling its heater to vary the amount of heat added to the water going to conduit 31. Although various types of temperature controllers are well known and available commercially, one particular type of controller that can be employed to advantage is the Sterl-Tronic S-6300 temperature control unit manufactured by Sterling, Inc., 5200 West Clinton Avenue, Milwaukee, Wisc.

The residence time of the thermoplastic material in die section 11 is such that at least the outer portions of the extrudate 37 have solidified before the extrudate 37 exits die section 11. A support 38 is situated to receive the extrudate after it issues from die section 11. If desired, support 38 can be provided with means for further cooling the extrudate and/or means for exerting a pulling force on the extrudate to aid in the extrusion.

Temperature sensing and transmitting means 41 measures the temperature of the molten thermoplastic material at the inlet of the long land die section 11 and automatically establishes a first signal 42 representative thereof. This signal 42 is applied to the measurement signal input of melt temperature controller 43. A setpoint signal 44 which is representative of the desired temperature for the molten thermoplastic material at the inlet of long land die section 11 is applied to the setpoint input of controller 43. Controller 43 automatically compares setpoint signal 44 and measurement signal 42 and automatically establishes a control signal 45 responsive to the magnitude and sign of the difference between signals 42 and 44. As is well known in the control art, control signal 45 bears a predetermined control relationship to the magnitude and sign of the difference between signals 42 and 44, e.g., control signal 45 can be directly proportional to the difference between signals 42 and 44, an integration thereof, a differentiation thereof, etc., or a combination of two or more such functions, e.g. the algebraic sum of such proportional value and a bias value, or the algebraic sum of such proportional value and an integration value. In the presently preferred embodiment controller 43 produces a control signal 45 which is the algebraic sum of a proportional factor, an integration factor and a bias factor. The control signal 45 is automatically applied to the heating means (not shown) in heating section 12 to manipulate the heat input to the thermoplastic material so as to maintain the temperature of the molten thermoplastic material at the inlet of the long land die section 11 at least substantially constant at the desired value therefor.

A tachometer 51 has a rotating sensing element 52 positioned in contact with the exterior surface of extrudate 37. Tachometer 51 automatically produces a D.C. measuring signal 53 which is representative of the instantaneous rate of extrusion of extrudate 37 from the die section 11. Signal 53 is applied to lag device 54 wherein the signal is delayed. Lag device 54 can be any suitable delay device, for example lag device 54 can consist of two identical first order lag circuits in series. The delayed signal 55, which is taken from the output of the first first order lag circuit, is a first order lag of signal 53, and is applied to the input of adder 56, the output 57 of which is applied to the measurement input of polymer feed rate controller 58. The delayed signal 59, which is taken from the output of the second first order lag circuit, is a first order lag of the first order lag of signal 53 (approximately equivalent to a second order lag), and is applied to the input of a digital rate panel meter 60. Lag device 54 is utilized in this embodiment as a low pass filter. As the tachometer sensor 52 operates at a very slow speed, the signal 53 has considerable spurious noise. The first stage of lag device 54 allows the signal 53 to pass through with just sufficient filtering action so that controller 58 does not follow the noise. The second stage of lag device 54 further smooths the signal for display by rate panel motor 60. Melt temperature measurement signal 42 is applied to the subtrahend input of substractor 61, while setpoint signal 44 is applied to the minuend input of subtractor 61. Signal 62, representing the algebraic difference between signals 42 and 44, is applied to one input of algebraic adder 56. A setpoint signal 63 representing the desired extrusion rate is applied to the setpoint input of polymer feed rate controller 58. The output signal 65 from controller 58 is responsive to the magnitude and sign of the difference between modified measurement signal 57 and setpoint signal 63. Thus output signal 65 bears a predetermined relationship to the magnitude and sign of the difference between signals 55 and 63 as well as to the magnitude and sign of signal 62. As with controller 43, controller 58 can have any suitable type of controller function known in the art, but preferably has a proportional plus integral function. Signal 65 is applied to the input of triac circuit 68. Triac circuit 68 is connected by wire 71 to one terminal of A.C. power source 72 and by wire 73 to one power terminal of vibrator mechanism 26. Wire 74 connects the other terminal of A.C. power source 72 to the second power terminal of vibrator mechanism 26. Triac circuit 68 varies the A.C. power going to vibrator mechanism 26 responsive to variations in the D.C. signal 65. The variation in A.C. power to vibrator mechanism 26 effects a corresponding variation in the feed rate of polymer particles to hopper 25. Thus the feed rate of polymer particles to the plasticization section of the extruder is automatically manipulated by the present control system to maintain the actual extrusion rate at least substantially constant at the desired value therefor. In the presently peferred embodiment wherein the output of polymer feed rate controller 58 is also responsive to the variations 62 of the temperature of the molten polymer entering the long land die section 11 from the desired temperature for the molten polymer entering the long land die section 11, the feed rate of polymer to the plasticization section of the extruder is automatically manipulated by the control system to maintain the extrusion rate at least substantially constant at the desired value therefor to the maximum extent permitted by the difference between the actual and desired values of the temperature of the molten polymer at the inlet of the long land die section 11.

The rotating sensing element 52 can be provided with means for periodically interrupting the light beam between light source 81 and a phototransistor 82, so that phototransistor 82 produces a series of pulses having a frequency correlated to the extrusion rate. The pulses from phototransistor 82 can be applied to an input of digital counter 83 wherein the pulses are counted as an indication of the extruded length of the current article being extruded beyond a reference point (e.g. the cutting element of cutter mechanism 85). When the length of the current article reaches the desired value, digital counter 83 can be employed to transmit a signal to solid state relay 84 to actuate cutter mechanism 85 to sever the portion of the extrudate downstream of cutter 85. The digital counter 83 can be provided with an automatic reset to zero when the extruded length of the current article downstream of cutter 85 reaches the desired value or a manual reset 86 can be employed when the relay 84 is omitted and the operator actuates the cutter mechanism 85. A digital display 87 can be connected to digital counter 83 to provide a visual indication of the current length of production beyond the reference point and/or the totalized length of production subsequent to a reference time point.

Temperature sensing and transmitting means 91 measures the temperature at the surface of the extrudate 37 at a point at least closely adjacent to the outlet of long land die section 11 and automatically establishes a measurement signal 92 representative thereof. The signal 92 is applied through the measurement input of extrudate surface temperature controller 93 to the subtrahend input of subtractor 94. A signal 95 which represents the desired extrudate surface temperature at the outlet of long land die section 11 is applied to the minuend input of subtractor 94 to automatically produce a signal 96 which bears a predetermined relationship to the magnitude and sign of the difference between the actual and desired extrudate surface temperatures at the outlet of die section 11. Signal 96 is applied to one input of adder 97 and to an input of multiplier 98. Signal 99 represents the multiplication product of signal 96 and a proportional gain factor 101 is applied to the input of integrator 102. The resulting integrated signal 103 is applied to a second input of adder 97 to produce signal 104 which is applied to one input of multiplier 105. The setpoint signal 36 is produced by multiplier 105 as the multiplication product of signal 104 and proportional gain factor 106. Thus signal 36 represents a proportional function plus integral function signal 96 and thus of the difference between the actual and desired extrudate surface temperatures at the outlet of die section 11. While the proportional plus integral function is presently preferred for controller 93, other suitable control functions can be employed as with controllers 43 and 58. With any suitable control function, controller 93 automatically adjusts the setpoint temperature signal 36 and thus the temperature of the cooling water passing through conduit 31 into heat exchanging relationship with the extrudate in long land die section 11 to thereby maintain the actual extrudate surface temperature at the outlet of die section 11 at least substantially constant at the desired value therefor represented by extrudate temperature setpoint signal 95.

While the regulation of the cooling water temperature in conduit 31 in order to achieve a desired extrudate surface temperature at the die exit is advantageous in that the cooling water temperature is readily controllable with a relatively fast response time, in many situations the cooling water temperature is limited in the degree to which it can be varied. For example in one installation due to equipment limitations, the cooling water temperature may be limited to a range of variation of ±10° F. from its operating point temperature, thereby permitting the use of the cooling water temperature to control extrudate surface temperature at the die exit only for variations of extrudate surface temperature within about ±5° F. of the desired extrudate surface temperature. Although extrudate surface temperature variations of more than ±5° F. are not frequently encountered in normal operation, they can occur occasionally. In addition, as final extrudate particle size can be adjusted by changing the extrudate surface temperature setpoint, occasionally by a major amount, it is desirable to have apparatus for automatically accomplishing this objective without causing major upsets in the control system. Moreover, in order to maintain the extrusion rate as close to the optimum design value as possible, it is frequently desirable to provide control functions for achieving a substantially constant extrudate surface temperature in addition to varying the cooling water temperature. The temperature of the molten polymer entering the long land die section temperature is subject to a substantial degree of control, but has a relatively long response time. Thus in order to provide for major changes in the extrudate surface temperature setpoint and for controlling deviations in surface temperature having a magnitude greater than a predetermined value, e.g. greater than ±10° F., the setpoint signal 44 to melt temperature controller can be manipulated responsive to the variations in signal 96 which are greater than the predetermined value, and the difficulty associated with the relatively slow response of the melt temperature can be overcome by providing the initial control response through changing the extrusion rate which has a much faster response. This is accomplished by applying signal 96 to the input of dead-band amplifier 107, the output signal 108 of which is applied to one input of adder 109 and to one input of multiplier 110. Dead-band amplifier 107 produces an output signal 108 with a value other than zero only when the magnitude of the difference between the actual and desired extrudate surface temperatures is greater than a predetermined value, e.g. ±3° F. Signal 111 represents the multiplication product of signal 108 and a proportional gain factor 112 and is applied to the input of integrator 113. The resulting integrated signal 114 is applied to a second input of adder 109. The extrudate surface temperature setpoint signal 95 is applied to one input of multiplier 115. The signal 116 represents the multiplication product of signal 95 and a proportional gain factor 117 and is applied to a third input of adder 109. The output signal 44 of adder 109 is applied to the setpoint input of melt temperature controller 43 and subtractor 61. Thus the melt temperature setpoint signal 44 varies responsive to the desired extrudate surface temperature (signal 95) and also responsive to the magnitude and sign of the difference between the actual and desired extrudate surface temperatures (signal 96) when said difference exceeds the predetermined value (represented by the dead-band of amplifier 107). The signal 57 to polymer feed rate controller 58 varies responsive to the desired extrudate surface temperature, the magnitude and sign of the difference between the actual and desired extrudate surface temperatures (signal 96) when said difference exceeds the predetermined value, and the magnitude and sign of the difference between the desired and actual temperatures for the molten polymer at the inlet of the long land die section 11. Since the input to the polymer feed rate controller is proportional to the deviation of the actual melt temperature from its setpoint, the polymer feed rate (extrusion rate) returns to the operating point value as the actual melt temperature approaches its setpoint. This has the effect of providing rapid response to large extrudate surface temperature variations and/or extrudate surface temperature setpoint changes while minimizing deviations in extrusion rate. The dead-band amplifier 107 eliminates undesirable variations in melt temperature and in extrusion rate due to small extrudate surface temperature deviations and/or small changes in extrudate surface temperature setpoint. Components 109, 110, and 113 form a proportional plus integral controller so that long deviation errors in extrudate surface temperature will provide permanent changes in the melt temperature setpoint 44 and allow the cooling water temperature controller 33 to operate within its proportional band.

Referring now to FIG. 2, resistor 121 connects wire 65 to a first input of operational amplifier 122, resistor 123 connects the first input of amplifier 122 to ground, and resistor 124 connects the second input of amplifier 122 to ground. The output of amplifier 122 is connected to the bases of each of transistors 125 and 126. The collector of transistor 125 is connected through capacitor 127 to ground and through resistor 128 to a +15 volts D.C. power source. The collector of transistor 126 is connected through capacitor 129 to ground and through resistor 131 to a -15 volts. D.C. power source. The emitter of transistor 125 is connected to the emitter of transistor 126, through feedback resistor 132 to the second input of amplifier 122, to the cathode of diode 133, to the anode of diode 134, and through resistor 135 to ground. Thus transistors 125 and 126 are connected to form a complementary emitter follower circuit. The cathode of diode 134 is connected through resistor 136 to a first end of variable resistor 137, while the anode of diode 133 is connected through resistor 138 to the first end of variable resistor 137. The second end of variable resistor 137 is connected to a 118 volts A.C. power source. Capacitor 139 and potentiometer 141 are connected in parallel between the cathode of diode 134 and the anode of diode 133, with the contactor of potentiometer 141 being connected through variable resistor 142 and capacitor 143 in series to ground. A diac 144 and the primary coil 145 of transformer 146 are connected in series between ground and the junction between variable resistor 142 and capacitor 143. The secondary coil 147 of transformer 146 is connected between the gate and the first anode of triac 148. Resistor 149 and capacitor 151 are connected in series between the second anode and the first anode of triac 148. Wire 71 is connected to the second anode of triac 148 while wire 73 is connected to the first anode of triac 148.

This circuit combines a single triac 148 with a diac 144 for triggering. The capacitor 143 is charged alternately positive and negative as the A.C. supply voltage between the second terminal of resistor 137 and ground varies. When the voltage across diac 144 reaches a reference value, the diac 144 breaks down and the gate circuit of triac 148 receives a pulse of current, and the triac 148 is brought into conduction if its anode voltage is of sufficient amplitude and proper polarity. The adjustment of the gain resistor 142 adjusts the slope of the voltage waveform. The balance potentiometer 141 can be used to center the voltage waveform precisely between the positive and negative breakdown voltage values with no input signal applied. The dead-band adjustable resistor 137 allows the voltage at the diac input terminal, i.e. the junction of resistor 142, capacitor 143 and diac 144, to just approach the diac breakdown voltage values with no input signal applied. Then if a positive D.C. signal is applied across resistor 135, the voltage at the diac input terminal is increased so that the positive breakdown voltage of the diac 144 is exceeded and diac 144 conducts. This in turn causes the triac 148 to conduct for the remainder of the duration of the line voltage half cycle. On the other hand, if a negative D.C. signal is applied across resistor 135, the voltage at the diac input terminal is lowered to the point that the negative breakdown voltage of the diac 144 is exceeded and diac 144 conducts in the other direction. This occurs during the opposite half cycle of the line voltage, so the triac 148 conducts through the remainder of the duration of the negative half cycle of the line voltage. The larger the magnitude of the input signal across resistor 135, the earlier in the respective half cycle that the triac 148 will conduct. Although the use of a constant-voltage transformer 146 avoids the problem of supply voltage variations, the phase shift of the transformer is dependent on the loading. If the phase shift is too great, the last diac conduction may occur after the anode voltage on triac 148 has changed polarity. If this occurs, the load is subject to a full half cycle of line voltage in the opposite direction from that which was just applied. If necessary, this can be avoided by utilizing optical isolation elements instead of transformer 146.

Although the invention has been illustrated in terms of an electronic system, any suitable automatic measuring components and automatic control components known in the art can be employed to construct the invention, including electrical components, pneumatic components, mechanical components, and combinations thereof, with either analog or digital output signals. In one presently preferred embodiment melt temperature controller 43 is a West 800 Time-proportioning temperature controller manufactured by West Instrument Division, Gulton Industries, 3860 N. River Road, Schiller Park, Ill.; lag circuit 54 is a lag card BO 3989, manufactured by Applied Automation, Inc., Pawhuska Road, Bartlesville, Okla.; and tachometer 51 is a model 60/A/05 tachometer manufactured by Wertronix, Inc., 2673 Culver Avenue, Dayton, Ohio. Adder 56 and polymer feed rate controller are collectively an Optrol® A controller card BO 3979 manufactured by Applied Automation, Inc., with signal 55 being applied to pin 15, setpoint 63 being applied to pin 13, signal 61 being applied to pin 14 and signal 65 being taken from pin 4; pins 6 and 12 being joined, pins 8 and 16 being joined, and pins 10 and 11 being connected by a front panel meter. While the invention has been illustrated as using the melt temperature variation signal 62 to modify the extrusion rate signal 55 because of the characteristics of the Optrol A controller card BO 3979, it is within the scope of the invention for the extrusion rate signal 55 to be applied to the measurement input of polymer feed rate controller 58 and for the melt temperature variation signal to be employed to modify the setpoint signal 63. In either event, the control signal 65 bears a predetermined relationship to the magnitude and sign of the difference between the actual extrusion rate and the desired extrusion rate as well as the magnitude and sign of the variation of the actual molten polymer temperature from the desired molten polymer temperature. Controller 93 and the controller formed by elements 109, 110 and 113 can be conventional proportional plus integral controllers. Dead-band amplifier 107 can be the one described by G. A. Korn in his article entitled "Control Applications for New Deadspace Limiter", published in Control Engineering, Vol. 9, No. 3, pp 91-92, March 1962.

While the polymer feeder has been illustrated as a vibrating mechanism, any suitable feeding means can be employed so long as the rate of feeding of the polymer particles to the polymer plasticization section of the extruder can be manipulated by the polymer feed rate controller 58. For example, a variable speed extruder screw could be employed in place of piston 15 with the screw being flood fed by a hopper immediately above the polymer inlet section so that the polymer feed rate to the polymer plasticization section of the extruder can be manipulated by varying the speed of the extruder screw.

While the measurement of the extrudate surface temperature has been described as being at the exit of long land die section 11, it is obvious that the actual measurement can be spaced several inches from the die exit so long as the measured temperature is at least substantially representative of the extrudate surface temperature at the die exit. While the control of the rate of withdrawing heat from the polymer in the long land die section 11 has been described in terms of varying the temperature of the cooling water in conduit 31, it is obvious that the cooling control can be achieved by varying the flow rate of the cooling fluid instead of or in addition to the varying of the temperature of the cooling fluid.

Reasonable variations and modifications are possible within the scope of the foregoing disclosure, the drawings and the appended claims to the invention. 

That which is claimed is:
 1. A method comprising feeding particles into a plasticization zone; heating said particles in said plasticization zone to provide molten material; passing the thus produced molten material through a long land die and removing heat from the material passing through said long land die to produce an extrudate having at least the outer portions thereof solidified upon leaving said long land die; utilizing automatic sensing means to measure the actual surface temperature of said extrudate at least closely adjacent to the exit of said long land die and to establish a first signal representative thereof; utilizing means to establish a second signal representative of the desired surface temperature of said extrudate at the exit of said long land die; utilizing automatic control means to establish, responsive to said first and second signals, a third signal having a predetermined relationship to the magnitude and sign of the difference between said actual surface temperature and said desired surface temperature; and utilizing automatic control means for varying, responsive to said third signal, the rate at which heat is removed from the material passing through said long land die to maintain said actual surface temperature at least substantially equal to said desired surface temperature.
 2. A method in accordance with claim 1 further comprising utilizing automatic sensing means to measure the actual temperature of the molten material at the inlet of said long land die and to establish a fourth signal representative thereof; utilizing means to establish a fifth signal representative of the desired temperature for the molten material at the inlet of said long land die; and utilizing automatic control means to manipulate, responsive to the difference between said fourth and fifth signals, the heating of the particles in said plasticization zone.
 3. A method in accordance with claim 2 wherein said material comprises a thermoplastic polymer, further comprising utilizing automatic sensing means to measure the actual rate of extrusion of said extrudate and to establish a sixth signal representative thereof; utilizing means to establish a seventh signal representative of the desired rate of extrusion of said extrudate; utilizing automatic control means to establish, responsive to said sixth and seventh signals, an eighth signal having a predetermined relationship to the magnitude and sign of the difference between said actual rate of extrusion and said desired rate of extrusion; and utilizing automatic control means for varying, responsive to said eighth signal, the rate at which said particles are fed into said plasticization zone.
 4. A method in accordance with claim 3 further comprising utilizing means to vary said fifth signal responsive to the magnitude and sign of said third signal when the magnitude of said third signal exceeds a predetermined value to reduce the magnitude of said third signal to less than said predetermined value.
 5. A method in accordance with claim 4 further comprising utilizing means to vary said eighth signal responsive to the magnitude and sign of the difference between said fourth and fifth signals.
 6. A method in accordance with claim 5 further comprising utilizing automatic means to establish, responsive to said sixth signal, a production signal representative of the length of the extrudate with regard to a reference point, and severing said extrudate into segments of predetermined length responsive to said production signal. 